Sensing catheter emitting radiant energy

ABSTRACT

A sensing catheter having an outer flexible sheath and a distal section containing a sensing system having a sensing means, a radiant energy providing means and radiation transmitting means, preferably all housed within a fluid channel.

This application is a Continuation-in-Part Application of U.S. Ser. No. 14/124,435, filed Dec. 6, 2013, as a National Stage Entry Application of PCT/US2012/040877, filed Jun. 5, 2012, which is a non-provisional application which claims benefit of U.S. Provisional Application 61/493,521, filed Jun. 6, 2011.

BACKGROUND OF THE INVENTION

This invention is in the technical field of medical instruments, in particular for sensing, especially vision equipped, catheters, for insertion in narrow body lumens or passages. As an example, urinary catheters with vision and/or other sensing devices have to fit within the very narrow confines and thin fragile walls of the urethra.

In a first consideration, this requirement drives such instruments to have a very small cross section and a well tapered entry portion at the tip to allow safe insertion with minimum patient discomfort or risk for procedure complications.

But in a second consideration, there are also major benefits to include multiple functionalities in the instrument to be inserted in the body. This may consist of a subset, or all of, multiple fluid passages, vision systems, illumination devices, mechanical instruments and energy emission devices for diagnostics, absorption or treatment. To fit this into the confines of a small diameter instrument with tapered entry section poses a major challenge. This has made it difficult to combine desired functionality. As one example, there are recent commercial developments in subminiature cameras for vision in the tip of endoscopes. However, the very restricted dimensions that are permissible in for instance urinary catheters, make it very challenging to fit even a state of the art subminiature camera and required additional functionality in the instrument tip.

Imaging fiber optic bundles have been applied for remote vision devices a distance away from the instrument tip. These have the disadvantage of high cost due to the precision sorted arrangement of fibers in both ends. They have also the particular disadvantage of poor image resolution in small diameter applications due to the limited number of fibers that can be fitted in a small cross section. This limits the image clarity for the operator and may result in more difficult decisions due to lack of small details in the image.

A particular requirement for some vision equipped catheters, for instance in urology, is that often catheters must stay in place for an extended time after insertion, for fluid drainage or other liquid handling purposes. This poses a challenge to conventional inserted advanced instruments that may include tip mounted cameras, illumination, sensors, actuators or other devices. There is a need to disconnect such devices for long term catherization since they may also impede the liquid flow if staying in place and also create patient discomfort. It would be an advantage if all such extra functions can be easily removed while catheter is in place and leave only fluid channels.

As instruments like catheters advance in the art of added functionality and features, there is a need to keep the cost down. This can be achieved by a system design that allows flexibility of providing added features only as needed for a particular situation. It would for instance be an advantage if there is a simple catheter sleeve utilized for all applications, plus an insert that can be tailored for the need of a particular procedure.

When electric devices like cameras, illumination, sensors, actuators and treatment energy sources are introduced in the inserted portion of catheters or endoscopes, there is also a need to connect them to the outside world. Various schemes have been suggested including wires embedded in catheter walls, miniature connectors in the catheter tip, or wireless transmission equipment in the catheter tip for power and/or data. All such methods are feasible in large diameter endoscopic applications but become more challenging for very small diameter applications, like urinary catheters with fluid handling and vision. The available space for payload inside such a catheter is just too small to economically include too many electric devices while creating reliable mating electric connections in liquid environment. Insulated electric cables permanently attached and sealed to devices inside the catheter and tip is one viable solution. It is also desired to keep the count of wires low to reduce electric wiring cross section area and improve reliability.

SUMMARY OF THE INVENTION

The present invention alleviates the current problems in packaging additional functionality in small diameter, tapered tip catheters and other similar medical instruments. It does this by a design that permits shared simultaneous use of a common shared cross sectional area in the catheter tip by multiple functions. For instance, irrigation or other clear liquid or gas passages or orifices may also have a second role as illumination guides for a patient observation device, or as energy guide for devices directing radiant treatment energy towards the patient.

In another aspect of the invention, the restricted cross section problem is solved by locating the energy source or sources behind the observation device in the length direction from the distal end catheter tip. The energy source location behind the observation device allows larger footprint illumination or treatment devices with more emitted power and model versatility. The radiated energy is then carried around the observation device by means of a reflective surface on the inside of the instrument hollow distal tip and optionally on the observation device housing, creating an annular light guide for illumination. The tip may optionally be made of a translucent material to deliver a combination illumination of the target of both reflected and transmitted light. This light guide may also simultaneously share the role as a liquid or gas channel, for instance for irrigation. The observation device may be a camera or other imaging device, or other radiant energy sensors like for radiant temperature, thermal imaging, reflected energy spectral analyzer, color, texture or fluorescence analysis. The illumination or treatment devices or sources may be one or more LED's, lasers, or other radiant energy sources utilized for patient observation, diagnostics or treatment. The type of radiant energy involved includes visible light, UV, infrared, microwave, RF, THz or X-ray or a combination thereof. The radiant energy may be one single type, or simultaneous multiple types, or alternated between energy types selected to provide desired medical results. This includes for instance forward vision for observing safe instrument insertion, visualization of internal surgical procedures, patient diagnostics, antimicrobial treatment, photo activation of drugs, and internal tissue phototherapy for healing.

In yet another aspect of the invention, the illumination or treatment source is remoted from the instrument tip and utilizes of one or more fiber optics bundles or optical fibers leading to a light exit fiber end behind the sensor and using reflective surfaces on the inside of the tip and optionally on the sensor housing, guiding light or other energy for illumination or treatment in the annular channel of the instrument tip, where this light guide may also serve as a liquid channel.

In yet another aspect of the invention, the imaging can also be achieved via an imaging fiber optics bundle as a sensor at the tip and locating a camera at the other end of the fiber bundle remoted from the patient.

In one different aspect of the invention, the catheter for insertion into a patient lumen consists of a passive outer sleeve and an instrumented inner assembly that is insertable and removable in the sleeve from the proximal end of the sleeve away from the patient. This inner assembly will accommodate functions that are not part of the outer sleeve, including camera, illumination and treatment devices, sensors, or it may alternatively house fiber optics for remote imaging and illumination, actuators or treatment sources.

In one additional aspect of the invention, the inner member may include one or more lumen for liquid, for instance for irrigation.

In another aspect of the invention, the inner member may contain instruments for vision, illumination, treatment devices, actuators, and also electric conductors, for instance camera and light source wires.

In yet another aspect of the invention, the inner member houses no additional devices but may act as just an additional fluid channel or a stiffener.

In yet another aspect of the invention, the inner member provides additional stiffness to the sleeve for insertion or withdrawal control.

In yet another aspect of the invention, the stiffness of the sleeve varies according to the length position of the instrument to match the anatomy profile of the patient and avoid collapse.

In yet another aspect of the invention, the sleeve may be constructed of a thin wall and light flexible material for improved patient comfort, while the removable inner member provides stiffness for insertion.

In yet another aspect of the invention, the inner member is positionable in the length direction of the sleeve, and removable while the sleeve remains inserted in the patient.

Thus, in accordance with the present invention, there is provided a sensing catheter for use in a narrow body lumen having a distal catheter section terminating in an inwardly tapered port and containing a sensing system comprising (1) a sensing means having a sensor for sensing a radiant energy from the lumen as the catheter travels through or stops within the lumen, (2) radiant energy providing means located in the distal catheter section behind the sensor and (3) radiation transmitting means for transmitting radiant energy emitted by the radiant energy providing means around the sensing means and into the body lumen.

More particularly, in accordance with the present invention, the distal catheter section also functions as a fluid or gas channel in which the sensing system sits. The fluid or gas channel will extend back to a fluid inlet or outlet port located in the proximal catheter section outside the patient.

In preferred embodiments of the invention, the sensing system is housed within a insertable and removable assembly which can be positioned within an outer catheter sleeve for use and then withdrawn, leaving a fluid channel.

In a more preferred embodiment of the invention, when the assembly housing the sensing system is in operable position within the catheter sleeve, a fluid channel is formed between outer parts of the assembly and the catheter sleeve while another fluid channel is present within the assembly, each fluid channel communicating with a separate port within the catheter distal section.

In one preferred embodiment of the invention, the radiant energy providing means is positioned behind and to the side of the front sensor of the sensing means, while in a more preferred embodiment, the radiant energy providing means is positioned behind and to the side of the entire sensing means.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1a shows a lengthwise cross section of the tip of a catheter, schematically illustrating the principle of illumination using reflected light from a light guide, two energy sources for illumination, and imaging using a camera.

FIG. 1b shows a lengthwise perpendicular cross section of the tip of a catheter, as annotated in FIG. 1 a.

FIG. 1c shows a lengthwise cross section of the tip of a catheter, schematically illustrating the principle of illumination using reflected light from a light guide, and imaging using a camera, while using one energy source for illumination and one energy source for diagnostics or treatment.

FIG. 1d shows a lengthwise cross section of the tip of a catheter, schematically illustrating the principle of with imaging using a camera, while using two energy sources for diagnostics or treatment.

FIG. 2a shows a lengthwise cross section of the tip of a catheter, schematically illustrating the principle of illumination using both reflected light and transmitted light from a translucent and reflective light guide, two illumination sources, and imaging using a camera.

FIG. 2b shows a lengthwise cross section of the tip of a catheter, schematically illustrating the principle of illumination using both reflected and transmitted light from a light guide, and imaging using a camera, while using one energy source for illumination and one energy source for diagnostics or treatment.

FIG. 2c shows a lengthwise cross section of the tip of a catheter, schematically illustrating the principle of illumination with imaging using a camera, while using two energy sources for diagnostics or treatment.

FIG. 3 shows a lengthwise cross section of the tip, schematically illustrating an alternate embodiment of illumination devices.

FIG. 4 shows a perpendicular cross section of the tip from FIG. 3, here taken at the location of the camera.

FIG. 5 shows a perpendicular cross section of the tip from FIG. 3, here taken at the location of the illumination.

FIG. 6a shows a lengthwise cross section of the tip of a catheter, schematically illustrating an alternate embodiment of illumination using dual fiber optics and vision using a camera.

FIG. 6b shows a lengthwise cross section of the tip of a catheter, schematically illustrating an alternate embodiment of one illumination energy source behind the camera and one diagnostics or treatment energy source using fiber optics.

FIG. 7 shows a lengthwise cross section of the tip of a catheter, schematically illustrating an alternate embodiment of imaging using fiber optics and illumination sources behind the fiber optics tip.

FIG. 8 shows a lengthwise cross section of the tip of a catheter, schematically illustrating an alternate embodiment of both illumination using fiber optics and imaging using fiber optics.

FIG. 9 shows a lengthwise cross section of a catheter with fluid channels, illustrating the principle of a complete assembly.

FIG. 10 shows a series of perpendicular cross sections of an embodiment of a catheter with fluid channels, with reference to marked letters A-E in FIG. 9.

FIG. 11 shows a lengthwise cross section of the sleeve and how the internal assembly can be moved in to the sleeve.

FIG. 12 shows a lengthwise cross section of the internal assembly.

FIG. 13 shows an optional electric diagram for the catheter, for the case where several additional electric devices must be included in the internal assembly.

FIG. 14 shows a lengthwise cross section of a different catheter embodiment with an alternate arrangement of fluid channels.

FIG. 15 shows a series of perpendicular cross sections of the catheter embodiment in FIG. 14, with reference to marked letters A-E in FIG. 14.

FIG. 16 shows a lengthwise cross section of an embodiment of a catheter with alternate fluid channels; here in conjunction with coaxial fiber optic illumination and vision.

FIG. 17 shows a series of perpendicular cross sections of the catheter embodiment in FIG. 16, with reference to marked letters A-Din FIG. 16.

FIG. 18 shows a lengthwise cross section of an embodiment of a catheter with alternate fluid channels in conjunction with fiber optic illumination and imaging and with a sealed inner sleeve to prevent contact between body fluids and the vision and illumination system.

FIG. 19 shows a series of perpendicular cross sections of the catheter embodiment in FIG. 18, with reference to marked letters A-Din FIG. 16.

FIG. 20 shows an illustration of nasogastric intubation (Prior art)

DETAILED DESCRIPTION OF THE INVENTION

This invention is best described by reference to each figure of the Drawing.

In FIG. 1a is illustrated the principle of the employment of the sensing system with a fluid channel. A catheter sleeve 1 has a tapered tip 2 for less traumatic and safer entry in patient lumen or narrow passages. On the interior side of the tip 2 is reflective surface 3 that directs the light or treatment radiation from one or more sources 5 a, 5 b into the patient, while passing around the camera 4 placed inside the tip 2. The sources 5 a and 5 b may be LEDs or lasers. By placing the sources behind the camera, space is gained for allowing larger components. The camera 4 may furthermore have a reflective exterior to improve illumination light guiding. The reflective surface 3 may have mirror finish or diffuse characteristics to achieve desired light patterns. The annular passage 8 between the camera 4 and the tip 2 may optionally also function as a fluid channel passing fluid or gas the same way as illumination light or other energy rays. This fluid can additionally serve as a means of keeping the camera lens area purged and clean. From an illumination standpoint, it is known that reflective surfaces act the same for interface to air or versus a liquid. The camera 4 may furthermore be slightly retracted behind the tip aperture for creating a clean fluid barrier for the vision. The light rays 6 emerging from the tip 2 illuminate the camera field of view 7 so the patient's interior can be observed.

In FIG. 1b is schematically illustrated a perpendicular cross section of the tip 2 as designated by the line X-X located at a point of substantially maximum diameter of the catheter distal section in FIG. 1 a. It is noted that the outside diameter of the camera D1 is less than the inside diameter of the catheter D2, forming annular channel 8 that may serve as both illumination path and fluid channel. The annular channel external diameter will contract close to the distal tip of the catheter. The diameter ratio DI/D2 may practically be in the range 0.2 to 0.8. Although everything here shown as circular cross sections, the shapes involved may also be rectangular, polygonal or elliptical.

In practice, the sensing catheter of the present invention will have a working outside maximum diameter of about 2 to 20 mm, preferably about 4 to 10 mm. Thus, the principles of the present invention can also be usefully employed in small diameter endoscopes requiring one or more fluid channels along with illumination or other provided radiant energy.

In FIG. 1c is illustrated the configuration from FIG. 1a , but here with an illumination energy source 5 a providing illumination rays 6 a, and a different diagnostics or treatment energy source 5 b providing diagnostics or treatment energy rays 6 b which here are shown by darker lines for clarity. The energy sources 5 a and 5 b may be activated simultaneously or alternately and may be one or more of each type.

In FIG. 1d is illustrated the configuration from FIG. 1a , but here with two diagnostics or treatment energy source 5 a, and 5 b providing diagnostics or treatment energy rays 6 b which here are shown by darker lines for clarity. The energy sources 5 a and 5 b may be activated simultaneously or alternately, providing similar or different energy types, and may be one or more of each type.

In FIG. 2a is illustrated the arrangement from FIG. 1, but here with the catheter tip 2 and reflective surface 3, made of a translucent or semi translucent material. Here, some light or other radiant energy rays 6 are reflected from the inside of the tip 2 similar to FIG. 1, but some rays 6 are also allowed to pass through the tip 2. This arrangement can be beneficial in creating different shape illumination patterns.

In FIG. 2b is illustrated the arrangement from FIG. 2a but here with an illumination energy source 5 a providing illumination rays 6 a, and a different diagnostics or treatment energy source 5 b providing diagnostics or treatment energy rays 6 b which here are shown by darker lines for clarity. The energy sources 5 a and 5 b may be activated simultaneously or alternately and may be one or more of each type.

In FIG. 2c is illustrated the arrangement from FIG. 2a but here with two diagnostics or treatment energy source 5 a, and 5 b providing diagnostics or treatment energy rays 6 b which here are shown by darker lines for clarity. The energy sources 5 a and 5 b may be activated simultaneously or alternately, providing similar or different energy types, and may be one or more of each type.

In FIG. 3 is shown a variation for one or more sources 5 a and 5 b, here mounted transversal to the camera 4 and illuminating via angled mirrors 10 a and 10 b. This allows sources with a wider foot print. The mirrors 10 a and 10 b can furthermore also serve to hold the sources 5 a and 5 b centered within the sleeve 1 or tip 2. The camera 4 may be centered in the tip via supports 9, which may be perpendicular to the mirrors 10 a and 10 b for minimum shading.

FIG. 4 shows a perpendicular cross section at the camera 4 of the configuration in FIG. 3. The camera is held in place or centered in the tip 2 of sleeve 1 by two or more supports 9 a, 9 b. The annular channel 8 provides illumination light guiding and optionally fluid flow.

FIG. 5 shows a perpendicular cross section at the sources 5 a, 5 b of the configuration in FIG. 4. The sources 5 a, 5 b may be held in place or centered in the tip 2 or sleeve 1 by the two mirrors 10 a, 10 b. The annular channel 8 provides flow on the side of the mirrors 10 a, 10 b.

FIG. 6a shows yet another variation on the sensing catheter from FIG. 1, here using one or more fiber optics or other flexible energy guide assemblies 20 a, 20 b that send light or other radiant energy around the camera 4 because the radiant energy is guided by the reflective surface 3 inside the catheter tip, plus, to aid in energy conveyance, the exterior of camera 4 may also be reflective. The fiber optics assemblies receive light or treatment energy from remote sources arranged outside of the patient.

FIG. 6b shows yet another variation on the sensing catheter from FIG. 1a , here using one illumination energy source 5 a behind the camera that directs rays 6 a to the patient, and a fiber optics or other energy guiding assembly 20 b that directs diagnostics or treatment radiant energy rays 6 b which here are shown by darker lines for clarity. The fiber optics assembly receives diagnostics or treatment energy from remote sources arranged outside of the patient.

FIG. 7 shows a variation on the imaging from FIG. 1a , here using a coherent fiber optics bundle 21 with an imaging lens 22 replacing the camera in FIG. 1a . Here, the camera is arranged to view the free end of the imaging fiber optics outside the patient. The fluid flow around the imaging fiber optics has the same characteristics as in FIG. 1a to share the annular channel for illumination and/or other purposes, and also helps to keep the fiber optics lens clean.

FIG. 8 shows a combination of FIG. 5 and FIG. 6a to utilize remote imaging as well as remote sources. Here, there is an imaging fiber assembly 21 as well as one or more illuminating or treatment fiber optics guides 20 a, 20 b.

FIG. 9 shows one embodiment of the device that was schematically illustrated in FIG. 1a , but now expanded with additional details. Fluid flow to the patient 40 enter the inner tubing 32, passes through the distribution channel 31 in the mounting block 30 and emerges from the annular channel 8 in the tip 2. Illumination or treatment sources 5 a, 5 b send light around the camera 4 though the same annular channel 8 via reflective surfaces 3. Camera 4 may be centered in the tip by supports 9. Fluid flow 41 from the patient enters the aperture 42 in the sleeve 1 and exits via the annular passage between inside of sleeve 1 and outside of inner tube 32. It is noted that for extra high flow rate from the patient, the flow 40 may be reversed and used together with flow 41 to drain the patient faster. The camera 4 (or other sensor) and illumination (or other radiant energy providing) devices 5 a, 5 b are mounted to a sealed mounting block 30 that holds these devices in place and encapsulates electric connections to the insulated cable 33 that may be fed through the inner tubing 32. In FIG. 9 are also annotated several locations A-E for perpendicular cross sections that are shown in next figure.

FIG. 10 shows a series of perpendicular cross sections from the embodiment of FIG. 9.

Section A shows the camera 4 centered in the annular channel 8 by supports 9 a, 9 b mounted to the camera.

Section B shows sources 5 a, 5 b in the mounting block 30 and the apertures for liquid flow in the annular channel 8.

Section C shows the arrangement of flow channel 31 in the mounting block 30 to conduct liquid flow towards the tip.

Section D shows the proximal end of the mounting block 30, here creating a seal between the tip section of the catheter and the long section. This creates-two separate fluid sections. The inner tube 32 is attached to the mounting block 30 and provides liquid flow to the tip and also houses and protects insulated electric cable 33.

Section E shows a cross section in line with the aperture 42 in the sleeve 1. Flow 41 from the patient enters the aperture 42 and is led away from the patient in annular passage between sleeve 1 and inner tube 32.

Now going to FIGS. 11 and 12, these show the embodiment of FIG. 9 by its main subassemblies, sleeve 1 including a tapered internally reflective tip, and the inner assembly 50 that consists of all other parts. The inner assembly 50 is inserted from the proximal end of the sleeve 1 and may also use a stop 1102 in the sleeve 1 to position it at a desired point. Optionally, the inner assembly 50 may also be positioned anywhere lengthwise inside the sleeve 1 without the stop 1102, and positioning may be guided by a vision system image inside the sleeve by internal markings, or all the way to partially extending from the tip as far as it can go.

By this arrangement using a simple and low cost outer sleeve 1 plus an inner assembly with more features, the invention provides flexibility to have different functionality internally using the same insertion sleeve. It also provides as options a completely disposable instrument with a low cost camera, or for re-use and sterilization of the inner assembly with costlier equipment. The inner assembly may thus range from a simple inner tubing to provide desired stiffness or liquid handling of a catheter, to full electro-optics instrumented versions for guiding insertion, diagnosis and treatment.

The other advantage with the arrangement of FIGS. 11 and 12 is the ease of removal of the inner assembly from a patient in i.e., urology extended time catherization. This leaves only the sleeve 9 in place after the visual, diagnostic or treatment insertion procedure is complete. The sleeve 1 may be light weight and have a soft and thin wall design for greater patient comfort and increased inside cross section and can also include local stiffening by selected materials to prevent folding collapse. Additional features known from prior art like retaining balloons on catheters and manifolds at the distal end may be incorporated without deviating from the spirit of the invention.

FIG. 13 shows how the invention can accommodate additional functions in the catheter without adding electric wires that interfere with the needed reliability and for minimum cross sectional area for the cable 33. An interface may be provided in the catheter tip that creates a bus structure for connecting additional devices like diagnostic sensors, actuators, and energy control for treatment.

As illustrated in the previous discussion of the embodiments of the invention depicted in the Drawing, the sensed radiant energy and the provided radiant energy are, preferably, both electromagnetic radiation, such as visible light, UV light, IR light, microwave energy, radio frequency energy, terahertz energy or X-ray energy. The radiant energy providing means can provide more than one type of radiant energy, for example, two types of radiant energy. One type of radiant energy can be provided for observation of the internal tissue, while a second type of radiant energy can be provided, for example, for treatment, diagnosis or healing. Where desirable, and practical, illumination need not be used, but one or more other radiant energy sources are provided to focus the same or a mixture of radiant energies onto an internal tissue site.

The catheter internal assembly can be retracted and another internal assembly containing different radiant energy source(s) can be substituted therefor. Even so, preferably the radiant energy providing means and sensing means cooperate to allow a visual inspection of the body lumen.

The sensing means used in the operation of the present invention is well known by itself, and comprises two main parts, the sensor and a conversion/transmitting device. For example, the sensor can be a lens of a camera or a lens operatively connected to a fiber optic bundle. Due to space limitations at the catheter tip and proximal to the catheter tip within the distal catheter section, the radiation providing means is positioned at least behind and to the side of the sensor, for example, the lens, while preferably and where possible, the radiant energy providing means is positioned behind and to the side of the entire sensing means, for example as shown in FIG. 1 a of the Drawing. As shown in FIG. 7 of the Drawing, with an elongated sensing means, the radiant energy providing means is positioned behind and to the side of the sensor, which is the imaging lens 22 in FIG. 7.

For diagnostic purposes, the sensing means can be selected in conjunction with the radiant energy providing means to provide a visual image, a thermal image, surrounding temperature, a spectral analysis, a color analysis, a texture analysis, or a fluorescence analysis.

Now going to FIGS. 14 and 15, these show a length section and cross sections of a different embodiment of fluid channels in the catheter, in connection with a camera and energy sources near the catheter tip that are arranged similar as in FIGS. 9 and 10. In this alternative design, the catheter sleeve cross section is now divided into two fluid flow sections. In FIG. 15E, it is shown an additional lumen 50 that carries flow 40 separated by a wall from the prior mentioned flow 41. One use of this is to provide liquid flow to the patient through lumen 50 for lavage, treatment or optics cleaning, while flow 41 may be body fluids or lavage return from the patient. The flow 40 in lumen 50 is directed into the annular channel 8 and to the patient as shown in FIG. 14 and in FIGS. 15 A, B and C. However, flows 40 and 41 may be used in reversed directions or in parallel flow for medical procedure needs.

It is noted that interior of inner tube 32 in the arrangement of FIGS. 14 and 15 is sealed from body fluids. One advantage with this arrangement is therefore improved protection and insulation of electrical wires 33 and their connections.

Although only one added fluid channel 50 is shown in FIGS. 14 and 15, it is understood that additional fluid channels may be added in a similar fashion.

Another advantage with the embodiment shown in FIGS. 14 and 15 is an inherent rotational registration of the vision and illumination system versus the catheter sleeve. As seen in FIG. 15C, the mounting block 30 for the optical components is prevented to rotate axially against the catheter 1 by means of the non-circular internal cross section of catheter 1. This has the effect that the image angular orientation is always true to catheter rotational position, and this makes the resulting image easier and safer to interpret for the operator.

Now turning to FIGS. 16 and 17, these show a length section and cross sections of a catheter similar as in FIGS. 14 and 15, but here for a different embodiment with coaxial fiber optic bundles for illumination and imaging. A coherent inner fiber bundle 21 together with a lens 22 provides vision to a remote imaging device. An outer coaxial fiber bundle 20 provides illumination for imaging and/or energy for treatment. As noted in FIG. 16, the outer fiber bundle 20 is not reaching all the way to the tip of the inner fiber bundle 21, but is cut shorter. This gives the advantage of reduced fiber bundle diameter at the tip, permitting a well tapered catheter tip and adequate flow and optical area in the annular channel 8. It is noted that the energy from the outer fiber bundle is reflected by inner surface 3 of the catheter tip and may also be reflected by the exterior of the imaging fiber bundle.

Another advantage of the fiber optic arrangement of FIGS. 16 and 17 is increased flexibility of the fiber optics portion near the catheter tip, due to reduced diameter. This makes the catheter easier to feed through tortuous body lumen paths.

Now turning to FIGS. 18 and 19, these show one further improvement of the arrangement basically described in FIGS. 16 and 17. It is noted an addition of a flexible inner sleeve 51 with an attached sealed frontal window 52, arranged to encapsulate the fiber optic imaging and illumination system with lens 22, an inner imaging fiber bundle 21 and an outer coaxial illumination fiber bundle 20. The inner sleeve 51 is translucent at least in the section near to the tip, to transmit light and other energy from the illumination fiber bundle 20 to the patient via the annular channel 8.

The purpose of the added inner sleeve 51 with sealed window 52 is to completely isolate the fiber optic imaging and illumination assembly from the patient tissue and body fluids. This gives the advantages of significantly longer optics life due to relaxed or no harsh sterilization for the optics assembly, and safer procedures due to utilizing only pre-packaged sterile and onetime use components in contact with patient tissue or body fluids. It is noted that the invention arrangement with illumination located further into the catheter than the vision, creates a smaller frontal area and improved possibility for utilizing this feature in a tapered tip catheter.

The sequence for utilizing the arrangement of FIGS. 18 and 19 may be as follows:

1) At manufacturing of the catheter, insert inner sleeve 51 from the operator end into catheter 1 all the way, for instance to a stop 1102 as shown in FIG. 11. This stop 1102 may also be arranged as a light detent holding the parts together during handling. 2) Now package and sterilize the catheter assembly. 3) At time of patient use, insert the fiber optic assembly into the sealed inner sleeve until the optics tip contacts the sealed window. Optionally, clear gel or liquid may be used for optical coupling between parts. 4) Intubate the patient by visual guidance. 5) With catheter still in place in the patient, pull out the fiber optics as well as the inner sleeve from the catheter sleeve 1. This step results into a large cross sectional flow area of the in-patient catheter sleeve, and comfort for the patient due to lightness, softness and less external attachments.

The general principles of the embodiment of FIGS. 18 and 19 for encapsulating and isolating the optical system may also be applied to direct camera and LED based optics.

Although the spirit of the invention has been primarily exemplified with a urinary catheter with vision, illumination and fluid handling, the invention can also be applied to catheters in other medical fields; medical or industrial endoscopes, and for other instruments that need to provide radiant energy and fluid handling capability in a confined cross sectional area. As examples of types of medical endoscopes that can usefully employ the inventive features of the present invention, there may be mentioned naso-gastric, gynecological, and pulmonary endoscopes.

One example that is well illustrating the needs and value for this invention is shown in FIG. 20 (Prior Art). In the common art of nasogastric intubation, there is a hidden risk for false navigation of devices into pulmonary tracts instead of the digestive system. This can result into very serious complications. Key requirements for such applications include safe and quick navigation, confirmation of location, assessment of internal patient conditions, adequate flow handling, treatment—and patient comfort. This invention is quite suitable to a variety of gastric procedures. Similar needs are obviously present in several other medical specialties.

This invention herein is described by examples of embodiment. The spirit of the invention also permits any combined features from different embodiments. Variations of the invention will be apparent to the skilled artisan. 

The invention claimed is:
 1. A flexible sensing catheter for insertion into and use within a narrow mammalian body lumen or passage, comprising: a flexible outer catheter sheath having a distal end for insertion into the body lumen or passage; a distal catheter section formed at a first end of the catheter sheath, wherein said distal section comprises an inwardly tapered distal first port having a distal tip aperture of reduced internal port diameter, said inwardly tapered distal first port comprising an annular reflective surface at an inside surface of said first port; a sensing system comprising: (i) a sensor device housed within said catheter distal section near the distal tapered first port and having a sensor for sensing a radiant energy directly from the lumen or passage as the catheter travels through or stops within the lumen or passage; and (ii) a radiant energy source positioned within said catheter distal section in a location proximal and near to the radiant energy sensor of said sensor device; the annular reflective surface adapted for directing radiant energy, provided by the radiant energy source, through an annular channel in the distal catheter section into the body lumen or passage; the annular channel formed between the outer sheath and the sensor device and operatively connected to said first port; and said radiant energy source adapted for transmitting the provided radiant energy through the annular channel in the distal section of the catheter, around the sensor device, and directly into the body lumen or passage through and from the tapered distal first port, said annular channel adapted to simultaneously conduct radiant energy and a fluid flow such that the fluid flow is adapted to travel in at least one fluid flow channel through the flexible sensing catheter to the mammalian body lumen or passage.
 2. The catheter of claim 1 wherein at least two said fluid flow channels are separated from each other by at least one length-wise wall that divides a cross-sectional area between the sensing system and the outer catheter sheath.
 3. The catheter of claim 2, where the at least two separate fluid flow channels are positioned between the sensing system and the outer catheter sheath and comprise a first fluid flow channel operatively connected to said annular channel and a separate second fluid flow channel operatively connected to a second port, one of said channels comprising a third channel coaxially arranged with regard to said channel.
 4. The catheter of claim 1 comprising a mounting block adapted to prevent rotation of the sensor device independent of catheter rotation.
 5. The catheter of claim 1 wherein said annular reflective surface at an inside surface of said first port is less than 100% reflective such that the transmission of a portion of said radiant energy occurs through the distal portion of said outer catheter sheath.
 6. A flexible sensing catheter for insertion into and use within a narrow mammalian body lumen or passage, comprising: a flexible outer catheter sheath having a distal end for insertion into the body lumen or passage; a distal catheter section formed at a first end of the catheter sheath, wherein said distal section comprises an inwardly tapered distal first port having a distal tip aperture of reduced internal port diameter said inwardly tapered distal first port comprising an annular reflective surface at an inside surface of said first port; a sensing system comprising: (i) a lens housed within said catheter distal section near the distal tapered first port and connected to a fiber optic bundle such that the fiber optic bundle is adapted to receive a radiant energy directly from the lumen or passage as the catheter travels through or stops within the lumen or passage, said fiber optic bundle adapted to connect to a remote sensor located outside a patient; and (ii) at least one fiber optic guide positioned within said catheter distal section in a location proximal and near to the fiber optic bundle connected to said lens, said at least one fiber optic guide adapted to enable connection to a remote energy source located outside the patient; the annular reflective surface adapted for directing radiant energy, provided by said at least one fiber optic guide, through an annular channel in the distal catheter section into the body lumen or passage; the annular channel formed between the outer sheath and the lens and operatively connected to said first port; and said at least one fiber optic guide adapted for transmitting the provided radiant energy through the annular channel in the distal section of the catheter, around the lens, and directly into the body lumen or passage through and from the tapered distal first port, said annular channel adapted to simultaneously conduct radiant energy and a fluid flow through the flexible sensing catheter to the mammalian body lumen or passage.
 7. The catheter of claim 6 wherein the fiber optic bundle and the at least one fiber optic guide are coaxially positioned within the catheter sheath, and the at least one fiber optic guide terminates proximal to the fiber optic bundle.
 8. A flexible sensing catheter for insertion into and use within a narrow mammalian body lumen or passage, comprising: a flexible outer catheter sheath having a distal end for insertion into the body lumen or passage; a distal catheter section formed at a first end of the catheter sheath, wherein said distal section comprises an inwardly tapered distal first port having a distal tip aperture of reduced internal port diameter, said inwardly tapered distal first port comprising an annular reflective surface at an inside surface of said first port; a sensing system comprising: (i) a sensor device housed within said catheter distal section near the distal tapered first port and having a sensor for sensing a radiant energy directly from the lumen or passage as the catheter travels through or stops within the lumen or passage; and (ii) a radiant energy source positioned within said catheter distal section in a location proximal and near to the radiant energy sensor of said sensor device; the annular reflective surface adapted for directing radiant energy, provided by the radiant energy source, through an annular channel in the distal catheter section into the body lumen or passage; the annular channel formed between the outer sheath and the sensor device and operatively connected to said first port; and said radiant energy source adapted for transmitting the provided radiant energy through the annular channel in the distal section of the catheter, around the sensor device, and directly into the body lumen or passage through and from the tapered distal first port, said annular channel adapted to simultaneously conduct radiant energy and a fluid flow such that the fluid flow is adapted to travel in at least one fluid flow channel through the flexible sensing catheter to the mammalian body lumen or passage; wherein the sensor device is an insertable and removable assembly for positioning within said outer sheath and said catheter comprises a flexible inner fluid isolation sleeve for isolating an inserted sensing device from the remainder of the catheter.
 9. The catheter of claim 8 wherein at least two said fluid flow channels are separated from each other by at least one length-wise wall that divides a cross-sectional area between the sensing system and the outer catheter sheath.
 10. The catheter of claim 9, where the at least two separate fluid flow channels are positioned between the sensing system and the outer catheter sheath and comprise a first fluid flow channel operatively connected to said annular channel and a separate second fluid flow channel operatively connected to a second port, one of said channels comprising a third channel coaxially arranged with regard to said channel.
 11. The catheter of claim 8 comprising a mounting block adapted to prevent rotation of the sensor device independent of catheter rotation.
 12. The catheter of claim 8 wherein said annular reflective surface at an inside surface of said first port is less than 100% reflective such that the transmission of a portion of said radiant energy occurs through the distal portion of said outer catheter sheath. 